Automated derivative view rendering system

ABSTRACT

A system and method for creating a derivative view from graphical data which is derived from native application data. The native application data may be extracted from a graphical application, such as a CAD application, converted to an intermediate or derivative format, and a derivative view of the graphic information produced by the original, native application is provided from the intermediate format.

CLAIM OF PRIORITY

This application is a continuation application of U.S. patentapplication Ser. No. 10/916,376, entitled “AUTOMATED DERIVATIVE VIEWRENDERING SYSTEM,” by Thomas, et al., filed on Aug. 11, 2004, (AttorneyDocket No. RIGHT-01000US0), which is a continuation-in-part of U.S. Pat.No. 7,092,974, entitled “DIGITAL ASSET SERVER AND ASSET MANAGEMENTSYSTEM,” by Thomas, et al., issued on Aug. 15, 2006, (Attorney DocketNo. RIGHT-01000US1), both incorporated herein by reference.

BACKGROUND

1. Field of the Technology

The present technology is directed to automated and dynamic repurposingof large amounts of digital graphic data or files.

2. Description of the Related Art

Graphical file information has become a major professional digital toolin business. Graphical file information can consist of items such asimages, animations, live video, and CAD drawings. Graphical informationis generally stored in vector graphics or raster graphics.

Traditionally, 2D and 3D graphical information has resided in pocketswithin an organization in different formats and physical locations whichare often inaccessible to various different departments within theorganization. Products used to create the different graphical files,marketing and other company departments. The costs associated withcreating downstream visual communications for documentation, trainingand support of complex tasks in the product lifecycle are skyrocketingas products become more complex and varied. The need to gain control ofthese processes in a coordinated manner is now a paramount concern forany product-oriented enterprise wishing to stay competitive.

The efficient and effective use and re-use of engineering and designassets can provide significant business and strategic advantage to anyengineering or manufacturing enterprise. In particular, the ability tocollate data from different graphical applications, used by, forexample, different departments, and output new views of the separate orcombined data, would be particularly useful.

SUMMARY

The technology, roughly described, comprises a system and method forcreating a derivative view from graphical data which is derived fromnative application data. In one aspect, the native application data isextracted from a graphical application, such as a CAD application,converted to an intermediate or derivative format, and a derivative viewof the graphic information produced by the original, native applicationis provided from the intermediate format.

In a further aspect, the technology is a method for creating a graphicview of a part. The method includes the steps of: extracting graphicaldata in a native application format; converting said graphical data fromthe native application format to a derivative graphical data format;receiving an instruction to provide a derivative view; and creating aderivative view of at least a portion of the graphical data from thederivative graphical data format.

In a further aspect, the graphical data includes a plurality of partsand may further include an assembly including a hierarchicalrelationship for said plurality of parts.

The step of converting may include providing a binary derivativegraphical file for each said part, and a hierarchical data file.

In a further embodiment, the technology is a method for creating anassembly visualization. In this embodiment, the method includes thesteps of: extracting graphical data from a CAD system, said graphicaldata including rendering data and a hierarchical structure; for eachpart in the assembly, creating a binary data representation of the part;receiving a new hierarchical structure for a new rendering view; andcreating a binary merge file of a rendering the new assembly based onsaid part assemblies and said new hierarchical structure.

In yet another aspect, the technology is a system for rendering aderivative view of graphical data. The system includes a native formatgraphical data import engine, a derivative format graphical data store;and a derivative view creation engine interacting with the derivativegraphical data store.

The present technology can be accomplished using hardware, software, ora combination of both hardware and software. The software used for thepresent technology is stored on one or more processor readable storagemedia including hard disk drives, CD-ROMs, DVDs, optical disks, floppydisks, tape drives, RAM, ROM or other suitable storage devices. Inalternative embodiments, some or all of the software can be replaced bydedicated hardware including custom integrated circuits, gate arrays,FPGAs, PLDs, and special purpose computers.

These and other objects and advantages of the present technology willappear more clearly from the following description in which thepreferred embodiment of the technology has been set forth in conjunctionwith the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a block diagram of a typical graphic file workflow inaccordance with the present technology.

FIG. 1B is an example of a user interface screen showing a firstalternative preview of a graphic in accordance with the presenttechnology.

FIG. 1C is a second example of a user interface showing a second exampleof a graphic preview in accordance with the present technology.

FIG. 2 is a block diagram of a processing system which may be utilizedin accordance with the present technology.

FIG. 3 is a block diagram of one embodiment of the system of the presenttechnology.

FIG. 4 is a flowchart showing the general process for creating aderivative rendered graphical view from original graphical data providedby a graphics design system.

FIG. 5 is an illustration of two views of a robotic arm.

FIG. 6 is a sample of part definitions in XML format.

FIG. 7A is a portion of a hierarchal structure defined in XML utilizedin accordance with the present technology.

FIG. 7B is a tree view of the XML structure shown in FIG. 7A.

FIG. 7C is a portion of a second type of graphical data defined in XMLformat utilized in accordance with the present technology.

FIG. 8 is a block level illustration of the substantiation of objects ina database in accordance with the present technology.

FIG. 9 is an illustration of the conversion of the hierarchal structureof an assembly to the flat file format of the present technology.

FIG. 10 is a flow chart illustrating the process for creating agraphical data file structure utilized in accordance with the presenttechnology.

FIGS. 11 through 15 are illustrations of the processing of hierarchalstructures of the robot assembly and associated XML hierarchical datastructures in accordance with the present technology.

FIG. 16 is a block diagram illustrating how data sources from differentdepartments can be merged to create a new rendered assembly.

DETAILED DESCRIPTION

The system of the present technology allows users to retrieveinformation from various types of CAD and other graphical developmentsystems and seamlessly author and integrate graphic files into standardbusiness software applications.

In particular, the system of the present technology allows users toimport graphical data from its native application format (or an exportof such data to a commonly understood format), and provide a new,derivative view (or multiple views and assemblies) of such data.

For example, for users who use Computer Aided Design (CAD) applicationsto create graphic images or files, the system of the present technologyallows such information to be imported, and altered to create new views,new assemblies, and/or be combined with information from otherapplications. The user can add images and data created in other 3D or 2Dimages applications, or perform other changes that are required to alterthe original graphical images to suit other purposes (“repurpose”).

In general, the system presents a method and apparatus for convertingnative graphical file information into a visualization using a moreuniversal data format. FIG. 1 is a flow diagram of the typical workflowof graphic files. Graphic files typically move through a workflowstarting from the creation of the graphic file 50, to data processing,storage and management 51, to the delivered file 52 (that is, use of thegraphic file in published documents etc). In typical computer systems,it is difficult to maintain graphic files, particularly updates andamendments to the files. The graphic file management system of thepresent technology works to process, store and manage 51 graphic filesas well as enable the tracking of enhancements, updating and amendments53 to graphic files stored in or linked to the server and database.

In one embodiment, native application data is converted to a UniversalGraphical Data Model (UGDM) which stores about the graphic files,including detailed image attributes, such as polygon counts, textureinformation, as well as information about the graphic files electronicfile size and date created.

In general, when native graphical file information is imported into thesystem, the system will automatically convert the information into asystem graphic file format (the UGDM), generally more efficient than thenative format. The system may also automatically create certain initialderivative views of the information, such as a thumbnail view of thefile.

The system of the present technology is capable of maintaining aconnection between the source data of a particular graphic file andincremental changes made to its other versions manually by users orautomatically by the server. Furthermore, data from multiple sources canbe managed. For example, if a number of graphic files are wanted to becombined to form one large graphic files but each of the graphic filesare in different formats as they were created by different computerusers, the system can combine these into one graphic file. This ispossible because the original file graphic data is extracted inconjunction with the original data's structural hierarchy informationand original coordinate systems. The UGDM data may be stored in adatabase or a file system, or simply used to create derivative views andthen discarded. Original coordinate systems can then be modified to fita larger global coordinate system and so spatial, logical or daterelated searches may then be made of the database.

The graphic file management system of the present technology storesgraphic files of 3D models and/or animation in such a way as to allowmultiple users to edit model or animation data that may be in anydifferent file formats. In the embodiment described herein, a graphicaldata format referred to as a “.RH format” is used.

The graphic file management system of the present technology allowsmultiple 3D graphic files containing assemblies, sub-assemblies andparts to be disassembled and recombined in new ways and into potentiallymuch larger assemblies than ever before possible for the purposes ofproject overview and management, interference checking, visualization,training, technical documentation, and many other purposes requiringmore lightweight data of potentially much larger assemblies than haveever before been combined. This is achieved by the system breakingexisting single files representing complex 3D model assemblies intosub-objects, sub-assemblies, or parts, and allowing separated viewingand control of these sub-assemblies or parts. The system treatsindividual 3D model files as assemblies, and combines these with otherassemblies or sub-assemblies as defined by other 3D model files togetherinto one single master assembly. Also the system enables applying ofoperations to each assembly, either before reducing an assembly orbuilding up an assembly. For example, a user could instruct the systemto show them everything in a one meter radius of a particular part of a3D model.

FIG. 1B shows a view screen 18 which in this example, shows a large twodimensional diagram of the graphic file named DV01410.X indicated asreference numeral 19. Also displayed in the preview screen 18 are theobject attributes of the graphic file 20, including but not limited tothe file name, the file format, the size of the file, when it was lastmodified, whether textures are included and whether it is animated. Alsoprovided on the preview screen 18 are other formats of the graphic file,generally indicated as 21 in FIG. 1B. An example of five other formatswhich can be created by the system and viewable by the user are shown inpreview screen 18, these are; a three dimensional preview in .RH fileformat, a three dimensional preview in viewpoint, a technicalillustration, a shaded technical illustration and a toon styleillustration.

If a user wishes to view any of the other formats 21 they can do so byusing their mouse to click over each of the text indicating which formatit is, for example, FIG. 1C shows the user interface 24 when viewing ofthe technical illustration 25 has been selected by the user.

FIG. 3 shows a functional block diagram of processing and datacomponents comprising the system of the present technology. As discussedin additional detail below, each of the components shown in FIG. 3 mayoperate on one or more processing systems. With reference to FIG. 2, anexemplary processing system for implementing the technology includes atleast one computing device, such as computing device 100. In its mostbasic configuration, computing device 100 typically includes at leastone processing unit 102 and memory 104. Depending on the exactconfiguration and type of computing device, memory 104 may be volatile(such as RAM), non-volatile (such as ROM, flash memory, etc.) or somecombination of the two. This most basic configuration is illustrated inFIG. 2 by dashed line 106. Additionally, device 100 may also haveadditional features/functionality. For example, device 100 may alsoinclude additional storage (removable and/or non-removable) including,but not limited to, magnetic or optical disks or tape. Such additionalstorage is illustrated in FIG. 2 by removable storage 108 andnon-removable storage 110. Computer storage media includes volatile andnonvolatile, removable and non-removable media implemented in any methodor technology for storage of information such as computer readableinstructions, data structures, program modules or other data. Memory104, removable storage 108 and non-removable storage 110 are allexamples of computer storage media. Computer storage media includes, butis not limited to, RAM, ROM, EEPROM, flash memory or other memorytechnology, CD-ROM, digital versatile disks (DVD) or other opticalstorage, magnetic cassettes, magnetic tape, magnetic disk storage orother magnetic storage devices, or any other medium which can be used tostore the desired information and which can accessed by device 100. Anysuch computer storage media may be part of device 100.

Device 100 may also contain communications connection(s) 112 that allowthe device to communicate with other devices. Communication mediatypically embodies computer readable instructions, data structures,program modules or other data in a modulated data signal such as acarrier wave or other transport mechanism and includes any informationdelivery media. By way of example, and not limitation, communicationmedia includes wired media such as a wired network or direct-wiredconnection, and wireless media such as acoustic, RF, infrared and otherwireless media. The term computer readable media as used herein includesboth storage media and communication media.

Device 100 may also have input device(s) 114 such as keyboard, mouse,pen, voice input device, touch input device, etc. Output device(s) 116such as a display, speakers, printer, etc. may also be included. Allthese devices are well know in the art and need not be discussed atlength here.

Returning to FIG. 3, as noted above, the technology includes a methodand system for creating derivative, post native graphical dataassemblies and renderings. In this context, it is noted that the term“render” may, to some, include a connotation of only producing twodimensional images. However, it should be understood that the term“render” in this context is used in the broader sense of any processingto convert graphics from a file into visual form, such as on a videodisplay. FIG. 3 is a block level diagram illustrating the functionalcomponents and data structures utilized in the system and method of thetechnology. It should be understood that the components of FIG. 3 can beimplemented on a single processing system and multiple processingsystems. For example, in one embodiment, a graphical designer willutilize a processing system 302 to create graphical data 302A. This data302A can be stored in data store 308 which can be located on theprocessing system 302, or a server processing system 306. This data willbe created in some graphical application and stored in thatapplication's native application data store 320. Likewise, user 304 canaccess system components 304A on a separate processing system wheresystem components 304A are separate applications running on suchprocessing system, or system components 304A may be stored on serverprocessing system 306 and accessed by user 304 directly. Hence, in oneembodiment both components 304A and 302A reside on a single processingsystem 306, and the graphical designer 302 and user 304 may access theserver processing system 306 via the same or different terminals. Inanother embodiment, data 308 is stored on a separate processing system302, components in box 310 themselves on a separate processing system,and the user 304 has a separate processing system.

Although such various embodiments exist, for purposes of the followingdescription, it will be assumed that the processing environment forsystem 300 of the present technology is a client/server, networkedenvironment such that graphical designer 302 has a unique processingsystem including a storage unit 308 which houses native graphical data302A, and communicates with a server processing system 310 using acommunication transport mechanism 312. Likewise, user 304 has uniqueprocessing system which includes components 304A of the presenttechnology and communicates with server 310 via a network communicationmechanism 312. It will be readily understood that the networkcommunication mechanism may comprise any combination of public orprivate networks, local networks and the like, such as the Internet.

In general, the graphical designer creates native application data whichis stored in data store 308. This native graphical source data maycomprise data from any of a number of different applications such asAutoCad®, Microstation®, Solidworks®, etc. all of which have data in anative format which is accessed in a datastore 320 directly by theapplication. Such native data may alternatively be stored on the filesystem in data files 322, or may be exported to alternative file formats324 such as IGES, (a common widely read CAD solids format,) supported bythe native application and which can be read and imported by the systemof the present technology.

System server 310 includes both system memory 315 and non-volatilememory 318. The system includes a processing engine 330 operating insystem memory 315 which instructs the processor described above withrespect to FIG. 2 to perform the task described herein.

As will be generally understood by one of average skill, the componentsof the system operating in system memory 315 may be stored innon-volatile memory 318 and loaded into system memory at runtime asinstructed by a system controller (not shown).

The importer script 326 is constructed to interpret the native graphicapplication data store, native application data stored in files 322, orapplication data stored in exported files 324 which are in a formatwhich the importer script can understand. It should be readilyunderstood that manufacturers of graphical systems generally provideAPIs to allow third parties to access their data in the particularformat that they use. If such APIs are not available, one of averageskill in the art can decode the data structure and provide the necessaryinstructions for importer script 322 to extract data information on thegraphical data in the files of interest.

To incorporate native application data into the system of the presenttechnology, the system server 310 uses an importer script 326 to convertthe native cad data 302A into the UGDM. In one embodiment, the UGDMcomprises hierarchal structure data 340 and binary (.RH) data 342. TheUGDM is, in essence, a derivative or intermediate data format which isunderstood by the system and a viewer application 346. The hierarchicalstructure data 340 is referred to as native hierarchical structure datasince it reflects the original, native structure of the data asgenerated by the native application. In one embodiment, the nativehierarchal structure 340 is an XML data structure file. The binary .RHdata 342 is described in additional detail below, but generally containsthe information necessary to reconstruct the original view of the file,and cerate a derivative view 344. The hierarchy data structure 340generally contains meta data on the information contained in the RH datafile 342. Examples of the meta data contained in the hierarch datastructure in XML format is shown in FIGS. 6 and 11-15.

When dealing with graphical data which comprises cad information, itwill be generally understood that cad information may consist ofassemblies of machines or designs which comprise a series of elementalparts. For example, a car is made up of suspensions, an engine and otherelements, each of which is made up of smaller parts. The organization ofthe hierarchy of assemblies in a cad structure is distinctive to eachorganization and depends on the logical organization which makes senseto each individual organization and business process. Accordingly, thedata in the .RH data file 342 can be on an atomic level, consisting of asingle file for each part, or an assembly level, consisting of all theinformation in a given assembly comprised of a number of parts. Wherethe information is provided in assembly, the hierarchal structure ofthat assembly is stored in the hierarchical data structure 340. Theimporter script 326 controls a processing engine to create both the XMLdata structure and the RH data 342. In general, this universal graphicaldata model is a more efficient mechanism of storing the graphical datathan, for example, the native cad data source 320.

Processing engine 330, XML data structure 340 and RH data 342 as well asthe importer script 326 are all shown as being within system memory 315.It should also be noted that multiple processing engines 330 may beprovided, with the processes described below with respect to assemblingparts and processing them in the different RH files performedsynchronously or asynchronously. In general, this is illustrated to showthat these elements can be temporarily stored while the processingengine 330 operate in accordance with the processes described herein. Itshould be understood that the native hierarchy structure data, RH data,importer script and other elements can be stored in non volatile systemmemory 318. Permanent storage of the native hierarchical data 345 and.RH data 342 in non volatile memory is selectable by a user depending onthe particular requirements of the server 310. When native hierarchystructure data and .RH data is stored in non volatile memory, suchstorage may be provided in a database or a simple file systemconfiguration. In one embodiment, an Oracle® system 9i or 10g databaseis utilized to store the data files.

Also shown in FIG. 3 is derivative rendering instructions 350. Thederivative rendering instructions 350 are utilized by the processingengine 330 to provide a derivative view 344 which is desired by a user.The derivative view 344 is a new rendered view of the graphical datawhich may, in various embodiments, be a different two dimensional orthree dimensional view of the original data. The derivative view 344 cancomprise a new assembly, a new graphic, or any number of different typesof graphical information. The derivative view may be viewed by a viewer342 as described below.

The derivative view 344 may be as simple as a thumbnail, or as complexas a different assembly of a number of different parts. The derivativeview is particularly useful for constructing a new assembly comprised ofdifferent components of a native cad assembly, or combining differentelements from different departments such as a wiring diagram andmechanical robotic arm. Such components are generally designed bydifferent departmental components of an organization.

In the example set forth below, construction of the new rendered viewfor a robotic arm is described. It should be recognized that thetechnology is not limited to processing assemblies or mechanicaldevices. The derivative view may be accessible to a viewer 346 whichunderstands the output of the processing engine. In one embodiment, thenew rendered view is a single .RH data file which may be read by theviewer. The viewer may include a web browser with a suitable 3D viewingplugin, a product such as Cosmos Creator available from Radish WorksLLC, or any other of a number of standard graphical data authoringviewing environments which are modified to read the output .RH datastructure.

In order for a user 304 to define the derivative view 344 that the userdesires from the native CAD graphical data 302A, the user may beprovided with a modification tool 352. The modification tool providesderivative rendering instructions 350 which operate the processingengines 330 to create the derivative view 344. Where the native data andderivative views comprise an assembly, the modification tool can modifythe native structure data 340 to create a derivative hierarchy structure345. It should be understood that the derivative hierarchy structure 345may be edited by a modification tool 352 or may be modified by a simpletext editor. As is well known, XML documents can be modified by textediting software. In addition, the derivative data (and native structuredata) need not be provided in XML format, but may be provided in othertext file formats. Generally, in one embodiment of the technology, themodification tool 352 outputs the derivative structure file 345 in amanner which reduces errors.

FIG. 4 shows an overview of the general process of the presenttechnology for creating a derivative view 344. While the process isdescribed in the context of creating a derivative CAD assembly, it willbe recognized that more simple forms of derivative views may also becreated. At step 402, native graphical data, in this case CAD data, fromthe native graphical application or a commonly understood export file isextracted from the file. As noted above, this information may beextracted using an API provided by the graphical system manufacturer,the known structure of the export file, or the data structure of thefile may be reverse engineered according to well known techniques. Thisstep is performed under control of the importer script 326. At step 404,the processing engine 330 under the control of importer script 326creates an .RH data file 342 and a native hierarchy structure file 340.The UGDM may take a number of different formats, and it should berecognized that the .RH data file is merely one implementation of thepresent technology. Other data structures can be used to store thegraphical data associated with the structural data of the graphicaldesign information 302A. Optionally, at step 406, native hierarchystructure file 340 and .RH file(s) 342 may be stored in non volatilememory 318. It should be recognized that information need not be storedif the importer script stores the data in system memory, the derivativeinstructions operate immediately to provide the derivative view 344, andthen the system discards the information.

In one aspect, where the graphical information 302A comprises a CADassembly comprised of various different parts, .RH data file 342 willcomprise a series of part.RH files, one for each part or at the mostelemental level of the structure in the assembly hierarchy. The part.RHassembly hierarchy structure will be stored in the native hierarchy datastructure 340.

Next, at step 408, derivative rendering instructions 350 controls theprocessing engine to construct a derivative view. Where the derivativeview is a new assembly, the processing engine will determine which partsin RH data 342 needs to use to assemble the derivative view 344 based onthe derivative hierarchy structure 345. Other changes to the derivativeassembly view, such as view styles (wire frame, toon, 2D, 3D, etc.) mayalso be controlled. Next, at step 410, the processing engine 330 willprocess the part level RH files as described further with respect toFIG. 10. Once all the part level RH files are processed, a single new RHfile of the derivative rendered view 344 is complete. Next, at step 412the derivative RH data file will be provided to viewer 346. Again, anoptional saving step 414 may occur to save the assembled view RH data344 to non volatile memory. The process is then completed.

An example of the creation of the derivative view from original datawill be described with respect to FIGS. 5, and 11 through 15. In thisexample, the original data is a CAD assembly of a robotic arm and thederivative view is a new assembly based on the original native assembly.

FIG. 5 shows two views 502 and 504 of a robotic arm including a numberof component parts thereof. FIG. 6 shows a portion 505 of an XMLrepresentation of a native parts in data structure file 340. The portion505 shows meta data of two parts of the robotic arm assembly shown inviews 502 and 504 identified by a part designator and a file identifier.As shown in FIG. 5, an exemplary part number 510 has a unique identifiernumber, which in this case is “12345”. Other meta-data elements whichmay be included in the part definition are a “description” 512, an“environment” identifier, a “level” identifier 516, a “version”identifier 518, an identifier of a parent part 520, and a unique partI.D. 522. In this example, part 12345 will have created for it a unique.RH file YY27J.RH will contain all the graphical rendering informationfor the part. Likewise another part 530 has its own unique identifyinginformation.

It should be understood that the type of meta data identified in portion505 is exemplary only. The meta data may be expanded to include anynumber and types of data. Because XML is extensible, new data types maybe defined and the XML data definition to include any number ofdifferent tags and types of data. As noted above, the hierarchalstructure 345 need not be an XML structure, but may in actuality be asimple text structure. This data may be utilized by the derivativerendering instructions 350 and incorporated into the modification tool352 to allow users even greater flexibility in rendering new renderedviews and incorporating different types of data.

While FIG. 6 shows an example of data which may be incorporated intoeach individual part, FIGS. 7A and 7B show an example of a portion of aXML data structure 340 illustrating the hierarchy between the number ofdifferent parts. FIG. 7A shows exemplary portion of an XML document 600which defines four different parts. A first part number 1234 identifiedat line 602 has a description tag 604, parent identifier 606 and an I.D.tag 608. Likewise part 2345 has a part I.D. number 610 includes its ownunique I.D. 612 and a tag 614 which identifies the file name of anyparts which make up the top level part. In addition, it is noted thatthe parent identifier tag 616 in part number 2345 identifies parent I.D.1111, which the I.D. of part number 1234. Likewise part number 3456identifies as its parent part number 1111 while part number 4567identifies as its parent part number 3456 (I.D. 333) and comprises anumber of different files (part 4_1 through part 4_8). The file namerefers to the original native data file designation. In the structureshown in FIG. 7A, the children parts are identified relative to theirparents. Parents may comprise sub-assemblies, as illustrated in FIG. 7B.As shown in FIG. 7B, parts 2222 and 3333 comprise a top part 1111.

There are two basic input types used for the XML part description shownin FIGS. 6 and 7A. CAD data is generally stored in terms of a bodyposition, which is an absolute position within a 3D model.Alternatively, CAD data is defined in terms of a 0, 0, 0 position and atransformation matrix. In the latter case, the XML will hold atransformation matrix for the data. The body position type of datarequires that data be stored individually for each instance of the partwhich occurs. In other words, eight bolts in the robot will requireeight part entries. The transformation matrix type of data enables CADdata to be stored once for each instance, and transformation data storedto enable the part to be moved to a different position as required. Inother words, the eight bolts only require one cad entry and eighttransformation entries.

An XML representation of transformation CAD data is illustrated in FIG.6C. For XML descriptions of parts including transformation data,coordinates are added as tags within the part description. The advantageof storing information in a transformation entry is that if the boltdrawing changes, only one entry in the cad data must change, and allsubsequent visualizations will include the new part. Using the bodyposition method, every entry for a bolt must be replaced. In the exampleshown in FIG. 7A, a body position method will require six differentparts, while the transformation index of FIG. 7C will require a singlepart with different transformation as illustrated by part number 4567.

FIG. 8 illustrates how XML documents are parsed into the database. Eachobject instance 702 includes a part I.D. and the transformation matrixof the individual part (if the part is stored in transform data). Anobject relationship class 704 stores the parent I.D. and the part I.D.for each part, and each object 706 has its I.D., file, and meta datafields.

FIG. 8 illustrates how the hierarchical structure of a CAD file isconverted to the light weight .RH file format. The hierarchicalstructure 800 is converted to a merged binary file comprising the part.RH files for each part. This merged .RH file, and the part .RH file,can be stored in a database as BLOBS. As should be readily understood,BLOBS are “binary large objects.” BLOBS generally comprise a largebinary file. When a database manager sees a BLOB file, it has no way ofunderstanding what is in the file. Therefore, the data structure storesthe BLOB in the database as a simple binary. It should be recognizedthat the storage of the RH file in the database is not required for thepresent technology. The binary format of the RH file allows theprocessing engine to rapidly generate new binary files to provide thenewly rendered view 344. Alternatively, the part.RH or merged .RH filescan be stored in a file system, as described above.

In general, the RH file is made of chunks. Each chunk describes whatinformation is to follow in later chunks and what each chunk is made of.Each chunk includes a primary chunk which has a primary I.D. and isalways the first chunk in the file. Any number of different types ofchunks may be provided. One advantage of this format is that in can beutilized to add and delete data and data types as requirements of thenative data change. Hence, the below description of the different typesof chunks included in an exemplary .RH file is not exhaustive.

Within the primary chunk are one or more optional main chunks. Thesechunks may include a THUMB, INFO, VERSION, ZLIB, PICTURE, MATERIAL,NODE, SCENEAMBIENT (scene ambient), SCENEILLUM (scene illumination),UNITS, key frame data (KF), control transform (CONTROLTM), parameter(CONTROL PRM) control, and SKIN (object skin). By way of example, the“thumb” chunk contains a thumbnail image in jpeg format. The “info”chunk contains ASCII information about a file and what applicationexported the native file format. A “version” chunk identifiesinformation on an associated API for the .RH formation, and a minimumversion of the system which may be able to view the file.

The .RH file may optionally include a compressed chunk, referred togenerally as a ZLIB. If the ZLIB chunk exists, the chunk is compressedand should be uncompressed with ZLIB (a standard compression library).Once the file is decompressed, the viewer 346 may import the informationas usual. This chunk may contain other chunks including, PICTURE,MATERIAL, NODE, SCENE AMBIENT, SCENE ILLUM, UNITS, KF, CONTROLTM,PRMCONTROL, AND SKIN.

Other examples of chunks which may be provided in the .RH format. A“picture” chunk may contain a single picture data. A “material” chunkcontains data on the type of material an object should be displayed asbeing composed of. It may include additional classes such as colors,opacity, specular level, glossiness, reflection, refraction, andshading. For example, a shader chunk may contain real-time shadinginformation and be a child of the material chunk. A mapping chunk maycontain a material map and be a child of the material chunk. It mayinclude an index chunk including an index of a picture, a map file, amap matrix, a map amount, and a mapping UV channel. The control TM chunkcan include items such as a rest matrix, a 3D pivot point, atransformation flag, a position track, a scale track, a rotation track,and a morph track. The PRM control chunk can include a targetidentifier, a controller parameter, the type of control parameter, and asingle key of the parameter controller. The skin chunk contains skindata of one mesh object. It can include a vertex list of 3D points, anarray of bone identifiers, a matrix of resting points, and skin data.

A “node” chunk may comprise a pointer to another chunk. A “sceneambient” chunk includes data on ambient color data. A “sceneillumination” chunk is a global scene illumination color. A units chunkcontains a unit identifier for the graphic. A KF chunk contains keyframing data. A control TM chunk may contain a single transformationcontroller. A PRM control chunk may contain single parameter controller.A skin chunk contains skin data for the object. A map chunk containsdata for one material map which may include an index of a picture and anRH file, a picture file name, an amount of mapping, the UV channel formapping, and other information.

The node class is the interface to nodes in the scene. It providesmethods to access various parts of the node such as its name,transformation, parents and children.

Other information which may be included in the RH file include lines,faces, light information, bone information, camera specific information,procedural specific information, sprite specific information, a positiontrack, a scale track, a rotation track, a morph track, a morph key, TCBdata, parameter control, skin information, and color information. Alines chunk may be provided which includes data such as line sizes, andline data. The lines chunk can be a child of the node data chunk. Afaces chunk can be a child of the node data chunk and include an arrayof all points on a face element and other face data. A BONE chunkcontains rendering data for human or animal bones. A CAMERA chunk can bea child of the node data chunk and local space camera positioninformation.

A generic chunk which may contain common data for a generic class mayalso be included and may comprise a child of the material or nodechunks. The information contained in the generic chunk can include aname string, an object information string, an object ID string, andother custom data

When the .RH file is delivered to a viewer application 346, it createsan object which represents an random, editable, polygon/polyline mesh.All objects rendered in the scene are represented in this class. Objectsconsist of points and faces, each point is specified by a pointstructure which is constructed using three coordinates X, Y and Z.Polygons can be stored without triangulation. Due to this feature, theinitial object structure is preserved, the process for writing plug insis simplified, and the quality of conversion to other formats is raised.The mesh object can store any vertex text and face information,including vertex colors, normals, texture coordinates, and the like. Theobject may be defined in solids form, a description of the object asmathematical entities like Non Uniform Rational B-Splines (NURBS). Thisformat is more directly related to the original CAD data than polygonsbut is effectively describing the same surface. This format can be usedso machines can tool a curve without approximating it with a number ofstraight lines. Hence, representations in rh format of geometries can besolids, polygons, and simpler curves limited to 2D for purposes ofdrawing. Additional meta information can also be stored.

FIG. 10 represents the process for creating individual parts into part.RH files, and creating a derivative view .RH file based on instructionsset 350. The process of FIG. 10 assumes that the native data structure340 and part .RH data 342 have been created by importer script 326 andexist in system memory 315 or non-volatile memory 318. If the system isrequired to render a simple thumbnail or other two dimensional image,the importer process 326 may simply pass of the .rh data to a conversionmethod, which renders a jpeg or other image format file, and the processof FIG. 10 need not be implemented. However, it is advantageous toconvert and store the any part data as in the .rh file format forfurther processing.

The process begins at step 902, where the new structure or hierarchy forthe assembly 345 is determined. If the derivative view 344 is simply athumbnail, an appropriate process can be called to create the thumbnail(from the .rh file) and the file output (as per step 412). That is,steps 916 and 920 will always be “no” and the thumbnail rendered as asimple part.rh file.

For purposes of this description, the process is described as operatingon an assembly comprised of a number of individual part files in thenative graphic application format. At step 906 the derivative hierarchalstructure 345 is parsed to determine the new assembly structure. Thehierarchy and part information is recorded into a data structure insystem memory for use in constructing the derivative view. This includesrecording the relationship between the parts in the hierarchal structureas described in the derivative structure file 345, and marking each partrecord “ready for processing” at step 908. At step 910, the first ornext part which is marked “ready for processing” is retrieved. At step912, the part retrieved in step 910 is converted to a part.RH file. Onceconverted to a part.RH file, at step 914, the part is flagged asprocessed. At step 916, the method determines whether additional partsat the same level in the hierarchy need to be processed. If so, it loopsto step 910. Once all the RH files for a given level in the hierarchyare processed, at step 918, the parts for this stage are merged into asub-assembly RH file. At step 920, the method checks whether additionalstages of sub-assemblies require processing, and if so, loops back tostep 910. The method loops until all parts which are part of thestructure are completed.

At the highest level in the hierarchy, at step 922, the assembly ismerged into a single .RH file. At this point, the system will have a RHfile of part level data for the parts stored in the new hierarchicalstructure.

Because different levels of the assembly can be processed by differentprocessing engines, asynchronous processing of the assembly may occur.That is, steps 910-920 can occur on different processing engines.

It should be recognized that this process may occur by importing andstoring all part.rh files for an assembly, and then processing the newassembly according to the steps in FIG. 10, or the processing of nativedata to part.rh files may occur simultaneously with the building of thederivative assembly as part .RH files are imported.

This process is graphically illustrated in FIGS. 11 through 15. FIG. 11illustrates a portion of the robot assembly shown in FIG. 5. In thiscase, a wrist portion 1102 and a flange portion 1104 are shown. Eachpart is originally constructed from an associated PRT file 1102A and1104A which are subparts of an assembly “top” 1105. In this case, asshown in FIG. 11, the wrist PRT file 1102A and flange PRT file 1104A areparts of the sub-assembly “top” and have been processed, so all are“flagged” as done. Because both of these files have been converted to RHpart files, they can be merged into a single top.RH file.

The graphical hierarchy illustrates a tree view of how component partfiles are used to construct assemblies. In FIGS. 11-15, the tree viewincludes check boxes and check marks. These check boxes represent what auser might see using the modification tool to select or de-select thesecomponents as part of the derivative view. In this case, a PRT file is afile associated with a 3D graphics program, such as ProEngineer, byParametric Technology Corporation or Unigraphics NX from UGS PLC.

Next, at FIG. 12, it will be noted that the “top” assembly 1105 iscompleted and a “stage 2” assembly 1109, which is the next level higherin the hierarchy, also includes a forearm part 1106 which is associatedwith the forearm PRT file 1106 a. Parts 1102, 1104 and 1106 illustratehow each new part file is added to the assembly view. Next, at FIG. 13,a new stage, stage 1112 is shown. Stage 3 includes a top axis part 1108and all of Stage 2. Top axis part 1108 is associated with a top axis PRTfile 1108. Likewise in FIG. 14, stage 4 is comprised of Stage 3, an“arms” subassembly 1120 which includes a small arm 1122 and large arm1124, as well as a first axis 1130. In accordance with FIG. 10, everyfew seconds, the data structure is interrogated by one or moreprocessing engines. Parts marked ready for processing are set to a queuein a processing engine. A processing engine retrieves parts within thequeue and creates the RH file for each part defined by the process inthe queue.

Assembly processing is handled in the same manner. Every few seconds atable in the database is interrogated to find assemblies such as stage2, stage 3, stage 4, stage 5 that are ready. Finally, using a mergeoperation, as indicated at step 922, all parts and subassemblies aremerged into a single assembly until all assemblies are done.Essentially, this is a single RH file. If the data structure is storedin system memory 315, it is technically not a file, but a serial streamhaving the same data structure as the RH format described above.

FIG. 15 illustrates the new derivative view of robot 1500 whichcomprises a number of stages (2-5) showing the various subpartsassembled together.

The merge operation begins with individual parts being converted to .RHfiles and when each part in the assembly is ready to process, theassembly itself is ready to be processed. This again is illustrated atFIG. 11 where two parts comprise a single top assembly. The methodcontinues until all parts and assemblies are flagged and set to becompleted. At each step, only the .RH parts and assemblies one levelbelow require merging. In this manner, different portions of theassembly can be processed by different processing engines 330.

It should be noted that in general, the RH file is derivative of theoriginal PRT file. In this current text, the RH file need not be theonly format which is created by the process in the engine.Alternatively, other formats, such as jpeg, bit maps, animations, andother formats, may be utilized in place of the .RH file. Other examplesinclude a thumbnail, a technical illustration, a cartoon style, a customangle, or any other file. As noted above, the RH file is a threedimensional file and can be rotated to the angle viewing the completemodel from any angle by the viewer 346. In all parts of process, statusflag is set in the database and once all children parts are in theassembly process, the status flag to the assembly is set as shown inFIG. 15.

To load the entire assembly into a viewer, the new rendered view 344 isnew .RH file which, in one example, can be called robot .RH. Once loadedfor viewing in viewer 346, the entire assembly and each individual partin the assembly can be viewed on its own or in conjunction with relatedparts, and get a greater understanding of the robot.

As illustrated in FIG. 16, the method and system of the presenttechnology also enables forming assemblies from data from differentdepartments of the enterprise, and from different graphical originatingprograms in the enterprise. For example, the control system for therobot 1500 may be developed by an electrical department. In this case,the electrical department will provide a set of data 302A1 asillustrated in FIG. 16. Different department, for example, themechanical department may have created the mechanical parts for therobot, generating the data source 302A2. In this case, even if datasource 302A1 and 302A2 are provided by different programs, such asAutoCad and MicroStation, the system of the present technology willparse them into the hierarchy and .RH part files, and can reassemblethem into a new rendered assembly 344. So, for example, if there is aninteresting view in the control wiring for the robot in conjunction withconnection points in the relative assembly, the robot then wiring areconverted to .RH files, and new XML hierarchy structure 345 is createdfor .robotRH and wiring.RH, and the process is run to create a brand newassembly 344.

The foregoing detailed description of the technology has been presentedfor purposes of illustration and description. It is not intended to beexhaustive or to limit the technology to the precise form disclosed.Many modifications and variations are possible in light of the aboveteaching. The described embodiments were chosen in order to best explainthe principles of the technology and its practical application tothereby enable others skilled in the art to best utilize the technologyin various embodiments and with various modifications as are suited tothe particular use contemplated. It is intended that the scope of thetechnology be defined by the claims appended hereto.

1. A method for creating a graphic view of a part, comprising:extracting graphical data in a native application format; convertingsaid graphical data from the native application format to a derivativegraphical data format; receiving an instruction to provide a derivativeview; and creating a derivative view of at least a portion of thegraphical data from the derivative graphical data format.
 2. The methodof claim 1 wherein the native application format is included in a datastore for a graphical application.
 3. The method of claim 1 wherein thenative application format is a commonly understood export file from anative application.
 4. The method of claim 1 wherein said graphical datais CAD data.
 5. The method of claim 1 wherein said step of convertingincludes providing a hierarchical data file.
 6. The method of claim 5wherein said hierarchical data file is in XML format.
 7. The method ofclaim 1 wherein the derivative view is a composite of a plurality ofbinary part files.
 8. The method of claim 7 wherein said receiving stepincludes receiving a modified hierarchical data structure for saidparts.
 9. The method of claim 1 wherein the derivative view is athree-dimensional view.
 10. The method of claim 1 wherein the derivativeview is a two-dimensional view.
 11. A computer implemented method forrendering a derivative view of graphical data, comprising: retrievinggraphical data in a first application format; converting said graphicaldata from the first application format to a derivative graphical dataformat; receiving an instruction to provide a derivative view; andcreating a derivative view of at least a portion of the graphical datafrom the derivative graphical data format.
 12. The method of claim 11further including storing the derivative graphical data prior to saidreceiving step.
 13. The method of claim 12 further including the step ofstoring a hierarchical data structure for said derivative graphical dataformat.
 14. The method of claim 12 wherein the step of creating includesretrieving the derivative graphical data format and the hierarchicaldata structure.
 15. A computer-readable medium havingcomputer-executable instructions for performing steps comprisingretrieving graphical data in a first application format extracting thegraphical data; converting said graphical data from the nativeapplication format to a derivative graphical data format; storing thederivative graphical data including a hierarchical data structure;receiving an instruction to provide a derivative view; and creating aderivative view of at least a portion of the graphical data from thederivative graphical data format.
 16. The computer-readable medium ofclaim 15 further including instructions for performing said creatingstep in a web browser.